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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2012 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(** Protocol version of this file. This is the date of the last modification. *)
(** WARNING: TO BE UPDATED WHEN MODIFIED! *)
let protocol_version = "20140312"
(** * Interface of calls to Coq by CoqIde *)
open Util
open Interface
open Serialize
open Xml_datatype
(* Marshalling of basic types and type constructors *)
module Xml_marshalling = struct
let of_search_cst = function
| Name_Pattern s ->
constructor "search_cst" "name_pattern" [of_string s]
| Type_Pattern s ->
constructor "search_cst" "type_pattern" [of_string s]
| SubType_Pattern s ->
constructor "search_cst" "subtype_pattern" [of_string s]
| In_Module m ->
constructor "search_cst" "in_module" [of_list of_string m]
| Include_Blacklist ->
constructor "search_cst" "include_blacklist" []
let to_search_cst = do_match "search_cst" (fun s args -> match s with
| "name_pattern" -> Name_Pattern (to_string (singleton args))
| "type_pattern" -> Type_Pattern (to_string (singleton args))
| "subtype_pattern" -> SubType_Pattern (to_string (singleton args))
| "in_module" -> In_Module (to_list to_string (singleton args))
| "include_blacklist" -> Include_Blacklist
| _ -> raise Marshal_error)
let of_coq_object f ans =
let prefix = of_list of_string ans.coq_object_prefix in
let qualid = of_list of_string ans.coq_object_qualid in
let obj = f ans.coq_object_object in
Element ("coq_object", [], [prefix; qualid; obj])
let to_coq_object f = function
| Element ("coq_object", [], [prefix; qualid; obj]) ->
let prefix = to_list to_string prefix in
let qualid = to_list to_string qualid in
let obj = f obj in {
coq_object_prefix = prefix;
coq_object_qualid = qualid;
coq_object_object = obj;
}
| _ -> raise Marshal_error
let of_option_value = function
| IntValue i -> constructor "option_value" "intvalue" [of_option of_int i]
| BoolValue b -> constructor "option_value" "boolvalue" [of_bool b]
| StringValue s -> constructor "option_value" "stringvalue" [of_string s]
let to_option_value = do_match "option_value" (fun s args -> match s with
| "intvalue" -> IntValue (to_option to_int (singleton args))
| "boolvalue" -> BoolValue (to_bool (singleton args))
| "stringvalue" -> StringValue (to_string (singleton args))
| _ -> raise Marshal_error)
let of_option_state s =
Element ("option_state", [], [
of_bool s.opt_sync;
of_bool s.opt_depr;
of_string s.opt_name;
of_option_value s.opt_value])
let to_option_state = function
| Element ("option_state", [], [sync; depr; name; value]) -> {
opt_sync = to_bool sync;
opt_depr = to_bool depr;
opt_name = to_string name;
opt_value = to_option_value value }
| _ -> raise Marshal_error
let of_value f = function
| Good x -> Element ("value", ["val", "good"], [f x])
| Fail (id,loc, msg) ->
let loc = match loc with
| None -> []
| Some (s, e) -> [("loc_s", string_of_int s); ("loc_e", string_of_int e)] in
let id = Stateid.to_xml id in
Element ("value", ["val", "fail"] @ loc, [id;PCData msg])
let to_value f = function
| Element ("value", attrs, l) ->
let ans = massoc "val" attrs in
if ans = "good" then Good (f (singleton l))
else if ans = "fail" then
let loc =
try
let loc_s = int_of_string (Serialize.massoc "loc_s" attrs) in
let loc_e = int_of_string (Serialize.massoc "loc_e" attrs) in
Some (loc_s, loc_e)
with Marshal_error | Failure _ -> None
in
let id = Stateid.of_xml (List.hd l) in
let msg = raw_string (List.tl l) in
Fail (id, loc, msg)
else raise Marshal_error
| _ -> raise Marshal_error
let of_status s =
let of_so = of_option of_string in
let of_sl = of_list of_string in
Element ("status", [], [
of_sl s.status_path;
of_so s.status_proofname;
of_sl s.status_allproofs;
of_int s.status_proofnum; ])
let to_status = function
| Element ("status", [], [path; name; prfs; pnum]) -> {
status_path = to_list to_string path;
status_proofname = to_option to_string name;
status_allproofs = to_list to_string prfs;
status_proofnum = to_int pnum; }
| _ -> raise Marshal_error
let of_evar s = Element ("evar", [], [PCData s.evar_info])
let to_evar = function
| Element ("evar", [], data) -> { evar_info = raw_string data; }
| _ -> raise Marshal_error
let of_goal g =
let hyp = of_list of_string g.goal_hyp in
let ccl = of_string g.goal_ccl in
let id = of_string g.goal_id in
Element ("goal", [], [id; hyp; ccl])
let to_goal = function
| Element ("goal", [], [id; hyp; ccl]) ->
let hyp = to_list to_string hyp in
let ccl = to_string ccl in
let id = to_string id in
{ goal_hyp = hyp; goal_ccl = ccl; goal_id = id; }
| _ -> raise Marshal_error
let of_goals g =
let of_glist = of_list of_goal in
let fg = of_list of_goal g.fg_goals in
let bg = of_list (of_pair of_glist of_glist) g.bg_goals in
let shelf = of_list of_goal g.shelved_goals in
let given_up = of_list of_goal g.given_up_goals in
Element ("goals", [], [fg; bg; shelf; given_up])
let to_goals = function
| Element ("goals", [], [fg; bg; shelf; given_up]) ->
let to_glist = to_list to_goal in
let fg = to_list to_goal fg in
let bg = to_list (to_pair to_glist to_glist) bg in
let shelf = to_list to_goal shelf in
let given_up = to_list to_goal given_up in
{ fg_goals = fg; bg_goals = bg; shelved_goals = shelf; given_up_goals = given_up }
| _ -> raise Marshal_error
let of_coq_info info =
let version = of_string info.coqtop_version in
let protocol = of_string info.protocol_version in
let release = of_string info.release_date in
let compile = of_string info.compile_date in
Element ("coq_info", [], [version; protocol; release; compile])
let to_coq_info = function
| Element ("coq_info", [], [version; protocol; release; compile]) -> {
coqtop_version = to_string version;
protocol_version = to_string protocol;
release_date = to_string release;
compile_date = to_string compile; }
| _ -> raise Marshal_error
end
include Xml_marshalling
(* Reification of basic types and type constructors, and functions
from to xml *)
module ReifType : sig
type 'a val_t
val unit_t : unit val_t
val string_t : string val_t
val int_t : int val_t
val bool_t : bool val_t
val option_t : 'a val_t -> 'a option val_t
val list_t : 'a val_t -> 'a list val_t
val pair_t : 'a val_t -> 'b val_t -> ('a * 'b) val_t
val union_t : 'a val_t -> 'b val_t -> ('a ,'b) union val_t
val goals_t : goals val_t
val evar_t : evar val_t
val state_t : status val_t
val option_state_t : option_state val_t
val option_value_t : option_value val_t
val coq_info_t : coq_info val_t
val coq_object_t : 'a val_t -> 'a coq_object val_t
val state_id_t : state_id val_t
val search_cst_t : search_constraint val_t
val of_value_type : 'a val_t -> 'a -> xml
val to_value_type : 'a val_t -> xml -> 'a
val print : 'a val_t -> 'a -> string
type value_type
val erase : 'a val_t -> value_type
val print_type : value_type -> string
val document_type_encoding : (xml -> string) -> unit
end = struct
type value_type =
| Unit | String | Int | Bool
| Option of value_type
| List of value_type
| Pair of value_type * value_type
| Union of value_type * value_type
| Goals | Evar | State | Option_state | Option_value | Coq_info
| Coq_object of value_type
| State_id
| Search_cst
type 'a val_t = value_type
let erase (x : 'a val_t) : value_type = x
let unit_t = Unit
let string_t = String
let int_t = Int
let bool_t = Bool
let option_t x = Option x
let list_t x = List x
let pair_t x y = Pair (x, y)
let union_t x y = Union (x, y)
let goals_t = Goals
let evar_t = Evar
let state_t = State
let option_state_t = Option_state
let option_value_t = Option_value
let coq_info_t = Coq_info
let coq_object_t x = Coq_object x
let state_id_t = State_id
let search_cst_t = Search_cst
let of_value_type (ty : 'a val_t) : 'a -> xml =
let rec convert ty : 'a -> xml = match ty with
| Unit -> Obj.magic of_unit
| Bool -> Obj.magic of_bool
| String -> Obj.magic of_string
| Int -> Obj.magic of_int
| State -> Obj.magic of_status
| Option_state -> Obj.magic of_option_state
| Option_value -> Obj.magic of_option_value
| Coq_info -> Obj.magic of_coq_info
| Goals -> Obj.magic of_goals
| Evar -> Obj.magic of_evar
| List t -> Obj.magic (of_list (convert t))
| Option t -> Obj.magic (of_option (convert t))
| Coq_object t -> Obj.magic (of_coq_object (convert t))
| Pair (t1,t2) -> Obj.magic (of_pair (convert t1) (convert t2))
| Union (t1,t2) -> Obj.magic (of_union (convert t1) (convert t2))
| State_id -> Obj.magic Stateid.to_xml
| Search_cst -> Obj.magic of_search_cst
in
convert ty
let to_value_type (ty : 'a val_t) : xml -> 'a =
let rec convert ty : xml -> 'a = match ty with
| Unit -> Obj.magic to_unit
| Bool -> Obj.magic to_bool
| String -> Obj.magic to_string
| Int -> Obj.magic to_int
| State -> Obj.magic to_status
| Option_state -> Obj.magic to_option_state
| Option_value -> Obj.magic to_option_value
| Coq_info -> Obj.magic to_coq_info
| Goals -> Obj.magic to_goals
| Evar -> Obj.magic to_evar
| List t -> Obj.magic (to_list (convert t))
| Option t -> Obj.magic (to_option (convert t))
| Coq_object t -> Obj.magic (to_coq_object (convert t))
| Pair (t1,t2) -> Obj.magic (to_pair (convert t1) (convert t2))
| Union (t1,t2) -> Obj.magic (to_union (convert t1) (convert t2))
| State_id -> Obj.magic Stateid.of_xml
| Search_cst -> Obj.magic to_search_cst
in
convert ty
let pr_unit () = ""
let pr_string s = Printf.sprintf "%S" s
let pr_int i = string_of_int i
let pr_bool b = Printf.sprintf "%B" b
let pr_goal (g : goals) =
if g.fg_goals = [] then
if g.bg_goals = [] then "Proof completed."
else
let rec pr_focus _ = function
| [] -> assert false
| [lg, rg] -> Printf.sprintf "%i" (List.length lg + List.length rg)
| (lg, rg) :: l ->
Printf.sprintf "%i:%a"
(List.length lg + List.length rg) pr_focus l in
Printf.sprintf "Still focussed: [%a]." pr_focus g.bg_goals
else
let pr_menu s = s in
let pr_goal { goal_hyp = hyps; goal_ccl = goal } =
"[" ^ String.concat "; " (List.map pr_menu hyps) ^ " |- " ^
pr_menu goal ^ "]" in
String.concat " " (List.map pr_goal g.fg_goals)
let pr_evar (e : evar) = "[" ^ e.evar_info ^ "]"
let pr_status (s : status) =
let path =
let l = String.concat "." s.status_path in
"path=" ^ l ^ ";" in
let name = match s.status_proofname with
| None -> "no proof;"
| Some n -> "proof = " ^ n ^ ";" in
"Status: " ^ path ^ name
let pr_coq_info (i : coq_info) = "FIXME"
let pr_option_value = function
| IntValue None -> "none"
| IntValue (Some i) -> string_of_int i
| StringValue s -> s
| BoolValue b -> if b then "true" else "false"
let pr_option_state (s : option_state) =
Printf.sprintf "sync := %b; depr := %b; name := %s; value := %s\n"
s.opt_sync s.opt_depr s.opt_name (pr_option_value s.opt_value)
let pr_list pr l = "["^String.concat ";" (List.map pr l)^"]"
let pr_option pr = function None -> "None" | Some x -> "Some("^pr x^")"
let pr_coq_object (o : 'a coq_object) = "FIXME"
let pr_pair pr1 pr2 (a,b) = "("^pr1 a^","^pr2 b^")"
let pr_union pr1 pr2 = function Inl x -> "Inl "^pr1 x | Inr x -> "Inr "^pr2 x
let pr_search_cst = function
| Name_Pattern s -> "Name_Pattern " ^ s
| Type_Pattern s -> "Type_Pattern " ^ s
| SubType_Pattern s -> "SubType_Pattern " ^ s
| In_Module s -> "In_Module " ^ String.concat "." s
| Include_Blacklist -> "Include_Blacklist"
let rec print = function
| Unit -> Obj.magic pr_unit
| Bool -> Obj.magic pr_bool
| String -> Obj.magic pr_string
| Int -> Obj.magic pr_int
| State -> Obj.magic pr_status
| Option_state -> Obj.magic pr_option_state
| Option_value -> Obj.magic pr_option_value
| Search_cst -> Obj.magic pr_search_cst
| Coq_info -> Obj.magic pr_coq_info
| Goals -> Obj.magic pr_goal
| Evar -> Obj.magic pr_evar
| List t -> Obj.magic (pr_list (print t))
| Option t -> Obj.magic (pr_option (print t))
| Coq_object t -> Obj.magic pr_coq_object
| Pair (t1,t2) -> Obj.magic (pr_pair (print t1) (print t2))
| Union (t1,t2) -> Obj.magic (pr_union (print t1) (print t2))
| State_id -> Obj.magic pr_int
(* This is to break if a rename/refactoring makes the strings below outdated *)
type 'a exists = bool
let rec print_type = function
| Unit -> "unit"
| Bool -> "bool"
| String -> "string"
| Int -> "int"
| State -> assert(true : status exists); "Interface.status"
| Option_state -> assert(true : option_state exists); "Interface.option_state"
| Option_value -> assert(true : option_value exists); "Interface.option_value"
| Search_cst -> assert(true : search_constraint exists); "Interface.search_constraint"
| Coq_info -> assert(true : coq_info exists); "Interface.coq_info"
| Goals -> assert(true : goals exists); "Interface.goals"
| Evar -> assert(true : evar exists); "Interface.evar"
| List t -> Printf.sprintf "(%s list)" (print_type t)
| Option t -> Printf.sprintf "(%s option)" (print_type t)
| Coq_object t -> assert(true : 'a coq_object exists);
Printf.sprintf "(%s Interface.coq_object)" (print_type t)
| Pair (t1,t2) -> Printf.sprintf "(%s * %s)" (print_type t1) (print_type t2)
| Union (t1,t2) -> assert(true : ('a,'b) CSig.union exists);
Printf.sprintf "((%s, %s) CSig.union)" (print_type t1) (print_type t2)
| State_id -> assert(true : Stateid.t exists); "Stateid.t"
let document_type_encoding pr_xml =
Printf.printf "\n=== Data encoding by examples ===\n\n";
Printf.printf "%s:\n\n%s\n\n" (print_type Unit) (pr_xml (of_unit ()));
Printf.printf "%s:\n\n%s\n%s\n\n" (print_type Bool)
(pr_xml (of_bool true)) (pr_xml (of_bool false));
Printf.printf "%s:\n\n%s\n\n" (print_type String) (pr_xml (of_string "hello"));
Printf.printf "%s:\n\n%s\n\n" (print_type Int) (pr_xml (of_int 256));
Printf.printf "%s:\n\n%s\n\n" (print_type State_id) (pr_xml (Stateid.to_xml Stateid.initial));
Printf.printf "%s:\n\n%s\n\n" (print_type (List Int)) (pr_xml (of_list of_int [3;4;5]));
Printf.printf "%s:\n\n%s\n%s\n\n" (print_type (Option Int))
(pr_xml (of_option of_int (Some 3))) (pr_xml (of_option of_int None));
Printf.printf "%s:\n\n%s\n\n" (print_type (Pair (Bool,Int)))
(pr_xml (of_pair of_bool of_int (false,3)));
Printf.printf "%s:\n\n%s\n\n" (print_type (Union (Bool,Int)))
(pr_xml (of_union of_bool of_int (Inl false)));
print_endline ("All other types are records represented by a node named like the OCaml\n"^
"type which contains a flattened n-tuple. We provide one example.\n");
Printf.printf "%s:\n\n%s\n\n" (print_type Option_state)
(pr_xml (of_option_state { opt_sync = true; opt_depr = false;
opt_name = "name1"; opt_value = IntValue (Some 37) }));
end
open ReifType
(** Types reification, checked with explicit casts *)
let add_sty_t : add_sty val_t =
pair_t (pair_t string_t int_t) (pair_t state_id_t bool_t)
let edit_at_sty_t : edit_at_sty val_t = state_id_t
let query_sty_t : query_sty val_t = pair_t string_t state_id_t
let goals_sty_t : goals_sty val_t = unit_t
let evars_sty_t : evars_sty val_t = unit_t
let hints_sty_t : hints_sty val_t = unit_t
let status_sty_t : status_sty val_t = bool_t
let search_sty_t : search_sty val_t = list_t (pair_t search_cst_t bool_t)
let get_options_sty_t : get_options_sty val_t = unit_t
let set_options_sty_t : set_options_sty val_t =
list_t (pair_t (list_t string_t) option_value_t)
let mkcases_sty_t : mkcases_sty val_t = string_t
let quit_sty_t : quit_sty val_t = unit_t
let about_sty_t : about_sty val_t = unit_t
let init_sty_t : init_sty val_t = option_t string_t
let interp_sty_t : interp_sty val_t = pair_t (pair_t bool_t bool_t) string_t
let stop_worker_sty_t : stop_worker_sty val_t = string_t
let add_rty_t : add_rty val_t =
pair_t state_id_t (pair_t (union_t unit_t state_id_t) string_t)
let edit_at_rty_t : edit_at_rty val_t =
union_t unit_t (pair_t state_id_t (pair_t state_id_t state_id_t))
let query_rty_t : query_rty val_t = string_t
let goals_rty_t : goals_rty val_t = option_t goals_t
let evars_rty_t : evars_rty val_t = option_t (list_t evar_t)
let hints_rty_t : hints_rty val_t =
let hint = list_t (pair_t string_t string_t) in
option_t (pair_t (list_t hint) hint)
let status_rty_t : status_rty val_t = state_t
let search_rty_t : search_rty val_t = list_t (coq_object_t string_t)
let get_options_rty_t : get_options_rty val_t =
list_t (pair_t (list_t string_t) option_state_t)
let set_options_rty_t : set_options_rty val_t = unit_t
let mkcases_rty_t : mkcases_rty val_t = list_t (list_t string_t)
let quit_rty_t : quit_rty val_t = unit_t
let about_rty_t : about_rty val_t = coq_info_t
let init_rty_t : init_rty val_t = state_id_t
let interp_rty_t : interp_rty val_t = pair_t state_id_t (union_t string_t string_t)
let stop_worker_rty_t : stop_worker_rty val_t = unit_t
let ($) x = erase x
let calls = [|
"Add", ($)add_sty_t, ($)add_rty_t;
"Edit_at", ($)edit_at_sty_t, ($)edit_at_rty_t;
"Query", ($)query_sty_t, ($)query_rty_t;
"Goal", ($)goals_sty_t, ($)goals_rty_t;
"Evars", ($)evars_sty_t, ($)evars_rty_t;
"Hints", ($)hints_sty_t, ($)hints_rty_t;
"Status", ($)status_sty_t, ($)status_rty_t;
"Search", ($)search_sty_t, ($)search_rty_t;
"GetOptions", ($)get_options_sty_t, ($)get_options_rty_t;
"SetOptions", ($)set_options_sty_t, ($)set_options_rty_t;
"MkCases", ($)mkcases_sty_t, ($)mkcases_rty_t;
"Quit", ($)quit_sty_t, ($)quit_rty_t;
"About", ($)about_sty_t, ($)about_rty_t;
"Init", ($)init_sty_t, ($)init_rty_t;
"Interp", ($)interp_sty_t, ($)interp_rty_t;
"StopWorker", ($)stop_worker_sty_t, ($)stop_worker_rty_t;
|]
type 'a call =
| Add of add_sty
| Edit_at of edit_at_sty
| Query of query_sty
| Goal of goals_sty
| Evars of evars_sty
| Hints of hints_sty
| Status of status_sty
| Search of search_sty
| GetOptions of get_options_sty
| SetOptions of set_options_sty
| MkCases of mkcases_sty
| Quit of quit_sty
| About of about_sty
| Init of init_sty
| StopWorker of stop_worker_sty
(* retrocompatibility *)
| Interp of interp_sty
let id_of_call = function
| Add _ -> 0
| Edit_at _ -> 1
| Query _ -> 2
| Goal _ -> 3
| Evars _ -> 4
| Hints _ -> 5
| Status _ -> 6
| Search _ -> 7
| GetOptions _ -> 8
| SetOptions _ -> 9
| MkCases _ -> 10
| Quit _ -> 11
| About _ -> 12
| Init _ -> 13
| Interp _ -> 14
| StopWorker _ -> 15
let str_of_call c = pi1 calls.(id_of_call c)
type unknown
(** We use phantom types and GADT to protect ourselves against wild casts *)
let add x : add_rty call = Add x
let edit_at x : edit_at_rty call = Edit_at x
let query x : query_rty call = Query x
let goals x : goals_rty call = Goal x
let evars x : evars_rty call = Evars x
let hints x : hints_rty call = Hints x
let status x : status_rty call = Status x
let get_options x : get_options_rty call = GetOptions x
let set_options x : set_options_rty call = SetOptions x
let mkcases x : mkcases_rty call = MkCases x
let search x : search_rty call = Search x
let quit x : quit_rty call = Quit x
let init x : init_rty call = Init x
let interp x : interp_rty call = Interp x
let stop_worker x : stop_worker_rty call = StopWorker x
let abstract_eval_call handler (c : 'a call) : 'a value =
let mkGood x : 'a value = Good (Obj.magic x) in
try
match c with
| Add x -> mkGood (handler.add x)
| Edit_at x -> mkGood (handler.edit_at x)
| Query x -> mkGood (handler.query x)
| Goal x -> mkGood (handler.goals x)
| Evars x -> mkGood (handler.evars x)
| Hints x -> mkGood (handler.hints x)
| Status x -> mkGood (handler.status x)
| Search x -> mkGood (handler.search x)
| GetOptions x -> mkGood (handler.get_options x)
| SetOptions x -> mkGood (handler.set_options x)
| MkCases x -> mkGood (handler.mkcases x)
| Quit x -> mkGood (handler.quit x)
| About x -> mkGood (handler.about x)
| Init x -> mkGood (handler.init x)
| Interp x -> mkGood (handler.interp x)
| StopWorker x -> mkGood (handler.stop_worker x)
with any ->
Fail (handler.handle_exn any)
(** brain dead code, edit if protocol messages are added/removed *)
let of_answer (q : 'a call) (v : 'a value) : xml = match q with
| Add _ -> of_value (of_value_type add_rty_t ) (Obj.magic v)
| Edit_at _ -> of_value (of_value_type edit_at_rty_t ) (Obj.magic v)
| Query _ -> of_value (of_value_type query_rty_t ) (Obj.magic v)
| Goal _ -> of_value (of_value_type goals_rty_t ) (Obj.magic v)
| Evars _ -> of_value (of_value_type evars_rty_t ) (Obj.magic v)
| Hints _ -> of_value (of_value_type hints_rty_t ) (Obj.magic v)
| Status _ -> of_value (of_value_type status_rty_t ) (Obj.magic v)
| Search _ -> of_value (of_value_type search_rty_t ) (Obj.magic v)
| GetOptions _ -> of_value (of_value_type get_options_rty_t) (Obj.magic v)
| SetOptions _ -> of_value (of_value_type set_options_rty_t) (Obj.magic v)
| MkCases _ -> of_value (of_value_type mkcases_rty_t ) (Obj.magic v)
| Quit _ -> of_value (of_value_type quit_rty_t ) (Obj.magic v)
| About _ -> of_value (of_value_type about_rty_t ) (Obj.magic v)
| Init _ -> of_value (of_value_type init_rty_t ) (Obj.magic v)
| Interp _ -> of_value (of_value_type interp_rty_t ) (Obj.magic v)
| StopWorker _ -> of_value (of_value_type stop_worker_rty_t) (Obj.magic v)
let to_answer (q : 'a call) (x : xml) : 'a value = match q with
| Add _ -> Obj.magic (to_value (to_value_type add_rty_t ) x)
| Edit_at _ -> Obj.magic (to_value (to_value_type edit_at_rty_t ) x)
| Query _ -> Obj.magic (to_value (to_value_type query_rty_t ) x)
| Goal _ -> Obj.magic (to_value (to_value_type goals_rty_t ) x)
| Evars _ -> Obj.magic (to_value (to_value_type evars_rty_t ) x)
| Hints _ -> Obj.magic (to_value (to_value_type hints_rty_t ) x)
| Status _ -> Obj.magic (to_value (to_value_type status_rty_t ) x)
| Search _ -> Obj.magic (to_value (to_value_type search_rty_t ) x)
| GetOptions _ -> Obj.magic (to_value (to_value_type get_options_rty_t) x)
| SetOptions _ -> Obj.magic (to_value (to_value_type set_options_rty_t) x)
| MkCases _ -> Obj.magic (to_value (to_value_type mkcases_rty_t ) x)
| Quit _ -> Obj.magic (to_value (to_value_type quit_rty_t ) x)
| About _ -> Obj.magic (to_value (to_value_type about_rty_t ) x)
| Init _ -> Obj.magic (to_value (to_value_type init_rty_t ) x)
| Interp _ -> Obj.magic (to_value (to_value_type interp_rty_t ) x)
| StopWorker _ -> Obj.magic (to_value (to_value_type stop_worker_rty_t) x)
let of_call (q : 'a call) : xml =
let mkCall x = constructor "call" (str_of_call q) [x] in
match q with
| Add x -> mkCall (of_value_type add_sty_t x)
| Edit_at x -> mkCall (of_value_type edit_at_sty_t x)
| Query x -> mkCall (of_value_type query_sty_t x)
| Goal x -> mkCall (of_value_type goals_sty_t x)
| Evars x -> mkCall (of_value_type evars_sty_t x)
| Hints x -> mkCall (of_value_type hints_sty_t x)
| Status x -> mkCall (of_value_type status_sty_t x)
| Search x -> mkCall (of_value_type search_sty_t x)
| GetOptions x -> mkCall (of_value_type get_options_sty_t x)
| SetOptions x -> mkCall (of_value_type set_options_sty_t x)
| MkCases x -> mkCall (of_value_type mkcases_sty_t x)
| Quit x -> mkCall (of_value_type quit_sty_t x)
| About x -> mkCall (of_value_type about_sty_t x)
| Init x -> mkCall (of_value_type init_sty_t x)
| Interp x -> mkCall (of_value_type interp_sty_t x)
| StopWorker x -> mkCall (of_value_type stop_worker_sty_t x)
let to_call : xml -> unknown call =
do_match "call" (fun s a ->
let mkCallArg vt a = to_value_type vt (singleton a) in
match s with
| "Add" -> Add (mkCallArg add_sty_t a)
| "Edit_at" -> Edit_at (mkCallArg edit_at_sty_t a)
| "Query" -> Query (mkCallArg query_sty_t a)
| "Goal" -> Goal (mkCallArg goals_sty_t a)
| "Evars" -> Evars (mkCallArg evars_sty_t a)
| "Hints" -> Hints (mkCallArg hints_sty_t a)
| "Status" -> Status (mkCallArg status_sty_t a)
| "Search" -> Search (mkCallArg search_sty_t a)
| "GetOptions" -> GetOptions (mkCallArg get_options_sty_t a)
| "SetOptions" -> SetOptions (mkCallArg set_options_sty_t a)
| "MkCases" -> MkCases (mkCallArg mkcases_sty_t a)
| "Quit" -> Quit (mkCallArg quit_sty_t a)
| "About" -> About (mkCallArg about_sty_t a)
| "Init" -> Init (mkCallArg init_sty_t a)
| "Interp" -> Interp (mkCallArg interp_sty_t a)
| "StopWorker" -> StopWorker (mkCallArg stop_worker_sty_t a)
| _ -> raise Marshal_error)
(** Debug printing *)
let pr_value_gen pr = function
| Good v -> "GOOD " ^ pr v
| Fail (id,None,str) -> "FAIL "^Stateid.to_string id^" ["^str^"]"
| Fail (id,Some(i,j),str) ->
"FAIL "^Stateid.to_string id^
" ("^string_of_int i^","^string_of_int j^")["^str^"]"
let pr_value v = pr_value_gen (fun _ -> "FIXME") v
let pr_full_value call value = match call with
| Add _ -> pr_value_gen (print add_rty_t ) (Obj.magic value)
| Edit_at _ -> pr_value_gen (print edit_at_rty_t ) (Obj.magic value)
| Query _ -> pr_value_gen (print query_rty_t ) (Obj.magic value)
| Goal _ -> pr_value_gen (print goals_rty_t ) (Obj.magic value)
| Evars _ -> pr_value_gen (print evars_rty_t ) (Obj.magic value)
| Hints _ -> pr_value_gen (print hints_rty_t ) (Obj.magic value)
| Status _ -> pr_value_gen (print status_rty_t ) (Obj.magic value)
| Search _ -> pr_value_gen (print search_rty_t ) (Obj.magic value)
| GetOptions _ -> pr_value_gen (print get_options_rty_t) (Obj.magic value)
| SetOptions _ -> pr_value_gen (print set_options_rty_t) (Obj.magic value)
| MkCases _ -> pr_value_gen (print mkcases_rty_t ) (Obj.magic value)
| Quit _ -> pr_value_gen (print quit_rty_t ) (Obj.magic value)
| About _ -> pr_value_gen (print about_rty_t ) (Obj.magic value)
| Init _ -> pr_value_gen (print init_rty_t ) (Obj.magic value)
| Interp _ -> pr_value_gen (print interp_rty_t ) (Obj.magic value)
| StopWorker _ -> pr_value_gen (print stop_worker_rty_t) (Obj.magic value)
let pr_call call = match call with
| Add x -> str_of_call call ^ " " ^ print add_sty_t x
| Edit_at x -> str_of_call call ^ " " ^ print edit_at_sty_t x
| Query x -> str_of_call call ^ " " ^ print query_sty_t x
| Goal x -> str_of_call call ^ " " ^ print goals_sty_t x
| Evars x -> str_of_call call ^ " " ^ print evars_sty_t x
| Hints x -> str_of_call call ^ " " ^ print hints_sty_t x
| Status x -> str_of_call call ^ " " ^ print status_sty_t x
| Search x -> str_of_call call ^ " " ^ print search_sty_t x
| GetOptions x -> str_of_call call ^ " " ^ print get_options_sty_t x
| SetOptions x -> str_of_call call ^ " " ^ print set_options_sty_t x
| MkCases x -> str_of_call call ^ " " ^ print mkcases_sty_t x
| Quit x -> str_of_call call ^ " " ^ print quit_sty_t x
| About x -> str_of_call call ^ " " ^ print about_sty_t x
| Init x -> str_of_call call ^ " " ^ print init_sty_t x
| Interp x -> str_of_call call ^ " " ^ print interp_sty_t x
| StopWorker x -> str_of_call call ^ " " ^ print stop_worker_sty_t x
let document to_string_fmt =
Printf.printf "=== Available calls ===\n\n";
Array.iter (fun (cname, csty, crty) ->
Printf.printf "%12s : %s\n %14s %s\n"
("\""^cname^"\"") (print_type csty) "->" (print_type crty))
calls;
Printf.printf "\n=== Calls XML encoding ===\n\n";
Printf.printf "A call \"C\" carrying input a is encoded as:\n\n%s\n\n"
(to_string_fmt (constructor "call" "C" [PCData "a"]));
Printf.printf "A response carrying output b can either be:\n\n%s\n\n"
(to_string_fmt (of_value (fun _ -> PCData "b") (Good ())));
Printf.printf "or:\n\n%s\n\nwhere the attributes loc_s and loc_c are optional.\n"
(to_string_fmt (of_value (fun _ -> PCData "b")
(Fail (Stateid.initial,Some (15,34),"error message"))));
document_type_encoding to_string_fmt
(* vim: set foldmethod=marker: *)
|